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Resilient Adaptive Neural Control for Uncertain Nonlinear Systems With Infinite Number of Time-Varying Actuator Failures

Kaixin Lu, Zhi Liu, Yaonan Wang, C. L. Philip Chen

2020IEEE Transactions on Cybernetics46 citationsDOI

Abstract

Existing studies on adaptive fault-tolerant control for uncertain nonlinear systems with actuator failures are restricted to a common result that only system stability is established. Such a result of not being asymptotically stable is a tradeoff paid for reducing the number of online learning parameters. In this article, we aim to obviate such restrictions and improve the bounded error control to asymptotic control. Toward this end, a resilient adaptive neural control scheme is newly proposed based on a new design of the Lyapunov function candidates, a projection-associated tuning functions method, and an alternative class of smooth functions. It is proved that the system stability is guaranteed for the case of an infinite number of failures and when the number of failures is finite, asymptotic tracking performance can be automatically recovered, and besides, an explicit bound for the tracking error in terms of <inline-formula xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink"> <tex-math notation="LaTeX">$L_{2}$ </tex-math></inline-formula> norm is established. Illustrative examples demonstrate the methods developed.

Topics & Concepts

Control theory (sociology)Tracking errorActuatorBounded functionNonlinear systemAdaptive controlComputer scienceExponential stabilityLyapunov functionStability theoryNorm (philosophy)Artificial neural networkFault toleranceProjection (relational algebra)MathematicsControl (management)AlgorithmArtificial intelligencePolitical scienceDistributed computingPhysicsLawMathematical analysisQuantum mechanicsAdaptive Control of Nonlinear SystemsAdaptive Dynamic Programming ControlNeural Networks Stability and Synchronization